Gas stove burner

ABSTRACT

This gas saving stove-head is designed to use in cooking at food shop or general household including for the other purposes. It could be applicable to all kinds of stove based on gaseous fuel by using engineering principle to accelerate speed of gas airflow mostly injected from the mouth of gas rest cylinder before reach to the cover through gas conduit into supply holes that are part of combustion. This could be made by assignment on the gas airflow that come out of the injector and traveled through leading conduit into gas rest cylinder and then raised upwards to the cover and supply holes to lose least buffet and resistant power of it. Simultaneously, speed of the airflow shall be accelerated by squeezing it to be smaller and after that heat arisen from combustion flame shall be wholly dammed up while outer cool air around the area shall be evacuated through little holes or vents to help efficient combustion. Rate between gas and air mixed is proper to help complete combustion and reduce soot and pollution problems. This could save gas and time taken in cooking much more than general stove in market. We could say that this gas saving stove-head helps save limited natural gas power for the benefit of our nation and people in general.

1. ChARACTERISTICS AND AIMS AT INVENTION

This gas saving stove-head that uses gas as fuel power in cooking orheat resource for other different purposes. Looking like those ingeneral, it is designed for the purpose of getting more heat but usingless gas including decrement in soot and pollution.

2. SCIENCES CONCERNING INVENTION

The first is that with Aero Dynamics concerning travel of gas's airflowthrough conduit into rest cylinder and acceleration of the gas airflowbefore passing the cover upwards to supply holes. The second is that ofThermo Dynamics concerning combustion, heat dam-up and evacuation ofouter cool air (oxygen) to help complete combustion.

3. BACK GROUND OF CONCERNING SCIENCE OR TECHOLOGY

Inner and outer characteristics of gas conduit and rest cylinder ofgeneral conventional high pressure gas stove-head are cylindrical. Gasrest cylinder is topped with a donut-like cover which the inner area Issmooth and flat to help gas flow through supply holes into combustionpart. The rest cylinder and the cover are both inside of cloak-like partto help protect wind blowing in and heat blowing out of it.

This gas saving stove-head is then designed to manage property shape anddirection of gas's airflow inside conduit and rest cylinder. The purposeis to accelerate the gas airflow before reaching supply holes to havehigh speed. After that, heat of flame-to pass out of supply holes isdammed up for losing less heat and outer cool air (oxygen) shall beevacuated inside to help much more efficient combustion. The cloak-likepart is designed at the criterion of entire cover to help protect heatblowing out of the part. Wings of it have little inlets to let outer airoxygen blow upward and to help most complete combustion and reducetemperature at the back of the stove (cook area) by shutting up the backof the part closely. There have been cylinders on wings of thecloak-like part to help keep and protect heat still inside.

The most important purpose of inventing this gas saving stove-head is toobtain most heat power in work and to consume less gas. Also soot andpollution arisen from incomplete combustion that are destroyingenvironment shall be by product decreased.

3. SUMMARY EXPLANATION OF FIGURES

FIG. 1 Air-receive socket of general gas stove-head

FIG. 2 General gas stove-head and its cover

FIG. 3 Cloak-like part of general gas stove-head

FIG. 4 Showing off important parts of gas saving stove-head

FIG. 5 Air-receive socket of gas saving stove-head

FIG. 6 Air-receive socket and gas conduit of gas saving stove-head

FIG. 7 Cut-front picture of the sides of injector air-receive socket gasconduit, and outer airflow mixed with gas come out of the injector ofgas saving stove-head

FIG. 8 Picture showing off inside characteristics of gas rest cylinderand enlarged picture of central area of the cylinder

FIG. 9 Side picture showing off inner characteristics of gas restcylinder

FIG. 10 Side picture showing off gas airflow movement and innercharacteristics of gas rest cylinder

FIG. 11 Picture showing off inner characteristics of gas rest cylinderopposite from gas conduit

FIG. 12 Picture showing off inner characteristics of gas nest cylinderas the same side as

FIG. 13 Partly cut-part pictures showing off characteristics andmovement directions of gas conduit the airflow passed through gasconduit and gas rest cylinder

FIG. 14 Picture looking from top side of gas rest cylinder

FIG. 15 Some cumulative cut-part pictures showing off innercharacteristics of gas rest conduit and gas airflow

FIG. 16 Side cut-front picture of cover of general gas stove-headshowing off gas airflow within the cover

FIG. 17 Cover of general gas in put upside down position

FIG. 18 Cover of stove-head in turn right side up position

FIG. 19 Heat dam-up cylindrical shape during placing on the cover

FIG. 20 Heat dam-up cylindrical shape of gas saving stove-head

FIG. 21 Picture showing off characteristics within cover of gas savingstove-head

FIG. 22 Cover of gas saving stove-head looking from top side

FIG. 23 Cover of gas saving stove-head looking from lower side

FIG. 24 Side cut-front picture showing off details of characteristicswithin the cover and heat dam-up cylindrical shape

FIG. 25 Half side cut-front picture showing off characteristics of gasairflow and fame come out of supply holes

FIG. 26 Cover and heat dam-up cylindrical shape of gas saving stove-headlooking from top side

FIG. 27 Partly cut-front picture of the cover and heat dam-upcylindrical shape of gas saving stove-head

FIG. 28 Partly cut-front picture of cover, heat dam-up cylindrical shapegas conduit, and gas rest cylinder showing off their innercharacteristics

FIG. 29 Cumulative pictures of the gas rest cylinder, cover, and heatdam-up cylindrical shape

FIG. 30 Cloak-like part of gas saving stove-head and enlarge picture ofthe area to place utensil on wings of the part

FIG. 31 Cumulative picture of gas saving stove-head

5. REVELATION OF COMPLETE INVENTION

Gas stove-head in general use Comprises of core important parts: a stopvalve, an air socket filling in air through gas conduit into restcylinder and supplying gas through at cover upwards supply holes forcombustion. There may be more than one of the said parts such as twopressure-control valves, two or more gas conduits. It is up tocharacteristics and purposes of work in use.

This gas saving stove-head comprises of core important part: cloak-likeparts (1), injector with pressure-control valve (2). through air socket(3). then gas conduit (4), into gas-rest cylinder (5), after that gassupplying through cover (6), passing supply holes (7), the cover beingtopped by dam-up cylinder (8), and another cylinder (9) topped overagain to help protect heat spreading out of the stove. Flame at supplyholes shall be ignited through gas-ignite pipe (10) as shown in FIG. 4.

Combustion is most complete at property and frequently mixed ratebetween gas and air. A gas stove in market now has an air-receive panellooks like natural longitudinal sections of an orange as shown inFIG. 1. Injector (11) needs air flowing inside to help combustion whilegas comes out of the injector needs air to mix properly through gasconduit (13). To let airflow (12) come inside frequently, the air socketis so pierced 8 holes (14) of about 10 to 15 mm in diameter (Length ofthe diameter is based on injector's size.) The 8 holes shall be placedat the front of inlet panel to ease air evacuated inside mostly rounddirection. Other 4 holes (15) are pierced under the socket to get enoughair when gas is using at highest level as shown in FIGS. 5, 6, and 7respectively.

After having passed through the injector (24) and traveled along the gasconduit (13)—before reach to the rest cylinder (28)(29) shall beaccelerated its speed by reducing conduit's size at lower part only alittle. At most end of the lower end of the gas conduit is a turn-uppart (21) as shown in FIGS. 9, 10 and 13.

This gas saving stove-head is designed to have outside of rest cylinderlooking and covering round at over top (16) in accordance with innercharacteristic of its kind. This inner characteristic of the restcylinder looking at over top is that the mouth of the rest cylinder atthe side near the gas conduit (79) shall be gradually by degrees smallin size ahead to the other end (36). This is a gas airflow vent form therest cylinder upwards to the cover (6) and supply holes (7). Roundcylindrical shape (17) inside at central of the rest cylinder shall becovered up (18) to prevent loss of heat of inner fire ring (57) likegeneral gas stove-head (19). There are some zigzag bends raising up alittle (20) to let heat of inner fine ring rotate (80) and get much moreheat as shown in FIGS. 2, 4, 8, 9, 14 and 15.

Inner of the rest cylinder is designed to have had characteristic ofcup-like round arc (22) that is different form general gas stove-head ofwhich has had ordinary cylindrical shape (23). The purpose to have hadcup-like round arc is to reduce veer of airflow after gas releasingthrough gas conduit as illustrated in FIGS. 2, 12, and 13.

After gas releasing from the injector (11) the gas airflow shall bestarted managing into more neat order of having upper (25) and under(26) ridges of curving arc inside of the gas conduit. The upper ridge isgradually higher and larger up (27) ahead to the cylindrical shape atthe central area of the rest cylinder. This is to let airflow from theconduit have much more speed and order including avoidance of buffetbetween the airflow and the cylindrical shape inside at central of therest cylinder (17) as illustrated in FIG. 13.

Gas airflow while travels through gas conduit (28)(29) shall beseparated into two ways (30) by arc ridges jutted out of the cylindricalshape inside at central of the rest cylinder. Some of the-said airflowis forced higher up to the mouth of the rest cylinder at central (31) bybuilding arc ridges at both sides (32) for enclosure of the abovetwo-way gas airRow (30). The two ridges stand erect each in front butgradually curve sloppily backwards (33) and bend upwards to the mouth ofthe rest cylinder (36). This could make more speed of gas airflow due tocurving surface. Curving swell at central (81) shall have had more orderof the airflow as illustrated in FIGS. 8, 9,10, 11, 12, 13, 14 and 15.

Some of airflow shall have more (34) and more speed by graduallyreducing inner size of the rest cylinder (35) and then raising higher upto opposite end of the gas conduit (36) and after that ahead to thesecond arc ridge (37) that is located nearly at back of the cylindricalshape. This second ridge looks like a curve wedge (Wedge shape is seenat overtop but curve shape seen at around sides.) that its pointed end(38) turns to the direction of gas airflow (34) and forcefully makesairflow left (39) separated into two ways (40)(41). This also could helpaccelerate more speed due to gradual pressure to smaller quantity. Theboth pointed ends (42) shall forcefully raised upwards to the mouth ofthe rest cylinder (36) at central but back of cylindrical shape. This isto make forcefully airflow to be separated into two directions—the firstis into outer ring of supply holes (44) while the second is into innerring (45) on top of the rest cylinder's cover (6) as illustrated inFIGS. 8, 10, 13 and 14.

These two pointed ends (42) are forced their directions bound for uppersupply holes (outer and inner rings) by angling upwards to the mouth ofthe rest cylinder. This is done for avoidance of buffet between left andright side airflow (43) bypassed central of cylindrical shape (17) andfor protection of heat loss before reach to supply holes as illustratedin FIG. 11.

The rest cylinder is closed at top by a donut-like cover with two rowsof supply holes (7)—lower row and upper one. Holes of upper row arelarger than of lower because of playing major role in combustion. Thereare 2 rings of supply hole—the outer ring (44) is for outer flame (53)while the inner ring (45) is for inner flame (57) as demonstrated inFIGS. 4, 24, 25 and 27.

General cover has its inner characteristic that is rather smooth andflat as demonstrated in FIG. 18. After most gas airflow inside of restcylinders (30)(34)(39)(40) and (41) is forced into vertical line, in anordinary and general cover (46), most airflow is rebounded back (47) asdemonstrated in FIGS. 13, 16, and 18. This gas saving stove-head istherefore designed to have had the cover of which its inner side is arcridge (49)(50) to receive airflow into supply holes and to reducerebound power as demonstrated in FIGS. 19, 21, 23, and 24.

Inner side of the cover is arc ridges located between outer ring ofsupply holes (44) and inner ring (45). These arc ridges are ranged formsmall size (49) to larger one (50). The small arc ridges (49) are as thesame side as the gas conduit to happen gab area at outer supply holes(44) and inner supply ones (45) that are ranged form large size (51) tosmaller one (52). Because gas airflow, while travels along the conduitis gradually squeezed into smaller quantity before reach supply holesboth outer (44) and inner (45) rings the gas airflow naturally gets morespeed.

Heat of inner ring flame (45), is dammed up by thick part at central ofthe rest cylinder (18) with zigzag bends raising up a little (20) to letheat rotate (80) and to help flame area at central (57) get much moreheat. At central of the rest cylinder there is a hole pierced for a knot(58) fixed it to the floor in case of no need of move as illustrated inFIGS. 9, 14, 24 and 25,

Inside of the cover at the side near the gas conduit (47) has got morewidth than both horizontal and vertical line and is gradually narrowahead to the opposite side (48). This is to get more and more higherspeed of gas airflow onto opposite side of the conduit (48) asillustrated in FIGS. 21, 23, and 24.

Then supply holes of upper ring are designed in cone-like shape (44)(45). Supply holes under the cover have diameter longer than outer onesto reduce resistant power of airflow before reach outer supply holes.These cone-like supply holes shall apply to both outer (44) and inner(45) rings as seen in FIGS. 24 and 25.

The cover (60 shall be topped over again by heat dam-up cylindricalshape to help base of flame (53) that is the hottest part to lose heat(54). Height of the cylindrical shape is not touched flame for no heattransmission to it as seen in FIGS. 24, 25, 27, and 28.

Heat spread out of combustion (54) shall be dammed up at the area ofheat dam-up cylindrical shape (8) that inside characteristic is cup-likeare. The shape is therefore designed to have cone-like holes (55) asmuch quantity as outer supply holes as seen in FIGS. 20. 25, and 26.

To let outside lower cool air (56) evacuate inside rapidly in help ofcombustion, each hole (55) of this heat dam-up cylindrical shape has itsdirection that the pointed end turning to the area of flame base (53) ora little over area of supply holes in tele-a-tele form (61). This couldhelp more complete combustion of outer ring flame (53) on the cover (6)and well decrement of soot problem as seen in FIG. 25 and 26.

If the cover is placed at right area that the smallest part (48) isturned to the front (the side opposite from conduit), the cover and therest cylinder are fixed together by holes Inside of the cover of thecylinder and bolts jutted out (60). The bolts are attached to the restcylinder at side opposite from gas conduit (36) as demonstrated in FIGS.8, 9, 13, 14 and 21.

Heat dam-up cylindrical shape is most efficient if holes around it (55)are at as the same right position as of supply holes tete-a-tete (61).The shape is therefore designed to have legs jutted out (62) of the restcylinder. The two legs are like rat teeth to protect move of the shapein work as demonstrated in FIGS. 8, 19<and 29.

From that time, heat dam-up cylindrical shape (8) of outer flame shallbe covered upon again by another outer ring of heat dam-up cylindricalshape (9) with a little space (64) from the first shape (80) to keep upheat at top of outer ring flame (53). The design is that the spacebetween the said cylindrical shapes is the principal of evacuating outercool air (65) to push top of outer ring flame (53) upwards to bottom ofutensil and to protect heat of top flame (54) spreading out of thecylindrical shape (9) as demonstrate in FIGS. 25 and 27.

Cloak-like part (1) is designed to cover the rest cylinder (5), thecover (6), and the heat dam-up cylindrical shapes (8) (9) more closely,to keep inside heat of the part, to have more well circulation of outerair (66), and to help ease more good combustion. Wings of the part (67)are pierced into little holes (68) to help outer cool air (66) float andprotect heat spreading out of the part but adding well oxygen intocombustion. To pierce little holes (58) like this is to make morestrength of the said wings (67), and to collect food crust as shown inFIGS. 29 and 30.

Three legs (69) of the cloak-like part shall reinforce more strength byadding thickness at them to support better utensils. Area of cylindricalshape that is section of the part (70) shall be closed upon all 3 sidesand pierced a hole to insert an igniter from outside (71). The partsection (70) shall be lifted higher (72) to dam up heat and to protectair pass through little holes (68) that may be effective to that underflame lifted (72). Some little holes (73) are provided for use ofigniter from outside in case of there be utensil upon as shown in FIG.30.

At the area of outer wings of the part is laid cylindrical shapes (74)around 3 sides welded into one piece of the part for loss no heat andprotection of outside wind. A space is made to be able to ignite fromoutside in case of there be utensil upon as shown in FIG. 30.

Three legs for utensil support (76) on wings of the part (67) aredesigned to be smaller and more tapering to avoid buffet of flame. Ontop of the legs (76) shall have arc ridge made higher up at a level (77)to support utensil that has more longer diameter than outer edge of thewings. The purpose is to help flame come upwards to most bottom ofutensil but made no buffet with cylindrical shapes welded to the area ofouter wings of the part (74) as shown in FIG. 30.

These 3 legs (76) have little arc ridges at central (78) to place panand utensil that has more shorter diameter than inner wings of the part.The purpose is to avoid touch of utensil bottom with the heat dam-upcylindrical shapes (7)(8) laid on the cover (6) to assign flame giveheat across utensil as shown in FIG. 30.

Follow through steps and explanations as above mentioned, heat withinthe part (utensil bottom) shall not be lost but could use heat moreeffectively. Stove gives more heat and takes short time to use gas. Thisis to save gas but make clear combustion due to proper mixture of airand gas that could help reduce soot and pollution problems.

1. Gas stove-head has air-receive socket (3) before entering into gasconduit (13) and is pierced eight round holes (14) of the same size atfront of air-receive socket (3) angling and spacing from the center ofthe same distance as shown in FIG.
 5. Four round holes on ridge ofair-receive socket (15) is designed for outer airflowing into mix withgas released from the injector (11) neatly and frequently (12) to helpbetter combustion while uses gas at most high scale as shown in FIGS. 5,6, and 7 or any chamber as the same size and distance as of the area ofthe socket or any chamber on its ridges that does duty of outer airevacuating in to mix with gas released the same way as above explained.2. Gas stove-head has unequal diameter inside its gas conduit-part toreach gas rest cylinder (21) has shorter diameter and the surface insidethere has characteristic of bending upwards a little to help acceleratespeed of gas airflow before reach to gas rest cylinders (28)(29) morerapidly and divert part of the airflow raised upwards to mouth of gasrest cylinder (79).
 3. The gas stove-head has got inner characteristicof its gas rest cylinder (22) that is cuplike round arc or the surfacethat has got beside and lower joint scars curving arc each could helpreduce resistant and buffet power of gas airflow (34) within gas restcylinder after the gas airflow (28)(29) traveled along gas conduit intothe cylinder as shown in FIGS. 12 and
 13. 4. Gas stove-head that has gotcharacteristic of curving arc (29) within its gas rest cylinder juttedout of cylindrical shape located at central of it or any other shapesinside the cylinder (17) that turns pointed end to gas conduit (13) areon duty of veering direction of gas airflow (28)(29) come out of gasconduit to get upwards to mouth of gas rest cylinder (19) and reducingbuffet power affected to cylindrical shape or others within the cylinder(17) as shown in FIGS. 8, 13, and 14 or to any jutted curving part atmouth of cylindrical shape or others within the cylinder (17) that areon duty of reducing buffet power or veering airflow or squeezing aircome out of gas conduit to raise upwards to mouth of the cylinder. 5.Gas stove-head has curving ridges (25)(26) laid horizontally within gasconduit (13) or arc ridges or other dented grooves within the conduitare all on duty of managing order of gas airflow (24) within the conduit(13), increasing more surface area of it, and adding more gas airflowrate before reach to the rest cylinder as shown in FIG.
 13. 6. Gas restcylinder of gas stove-head has got characteristic of ridges standingerect in front (32) but gradually curving sloppily backwards (33). Theseridges located besides cylindrical shape within the cylinder (17) andlooked like curve line if looks at top side (32) are for enclosure ofgas airflow come out of gas conduit (30) and raise upwards to mouth ofthe cylinder (31) and gas left (34) shall have more speed due to travelalong curving surface (33) and or narrower as illustrated in FIGS. 9,13, and
 14. 7. Gas stove-head has got characteristics within gas restcylinder (17) that is enclosing its inner cylindrical shapes of whichhave different size. The size near gas conduit (79) is varied in form ofgradually smaller ones (35) and shallower at both side ahead to theother ends (36). This difference in size are on duty of acceleratingmore speed of gas airflow (30)(32)(34)(39)(40) (41) having come out ofgas conduits (28)(29) ahead to opposite side of conduit (36) asillustrated in FIGS. 8, 9, 13, and
 14. 8. Gas stove-head has gotcharacteristics within gas rest cylinder that is enclosing cylindricalshapes or any other shapes within the cylinder (17) at the opposite endof gas conduit (36) and raised upwards (42) are all on duty of reducingor veering buffet or crash together of gas airflow come out of gasconduits (39)(40)(41) and bypassed the said shapes or others within thecylinder (17) to reduce loss of power or speed of gas airflow (43)before getting upwards to mouth of gas rest cylinder (36) as illustratedin FIGS. 11, 12, and
 14. 9. Gas stove-head has got characteristicswithin gas rest cylinder (17) of which are smaller as from the side neargas conduit (79) to force gas airflow get more speed during bypassingcylindrical shape (17) of both sides ahead to nearly the opposite end(36). A wedge to separate gas airflow is located to face with there. Thewedge looks at beside like curving ridge but like curving ridge at topside (38) turning its pointed end in opposite direction of gas airflow.The wedge plays roles of part of the airflow (39) to be raised upwardsto mouth of gas rest cylinder and forced the airflow separating apart(40)(41) while its speed is higher and lifted afloat (43) or like anyother curving ridges located opposite gas conduit (36) or back of innercylindrical shape (17) that are on duty of accelerating speed of gasairflow or veering buffet or crash of the airflow or separating theairflow into directions desired as illustrated in FIGS. 9, 11, 12, and13.
 10. Gas stove-head has got unequal inner characteristics of thecover—the side near gas conduit (47) is ordinary but gradually narrowerahead to the side opposite from gas conduit (48)—that plays roles offorcing gas airflow (30)(32)(34) come out of gas rest cylinder to havemuch more speed before reach to outer (44) and inner (45) ring supplyholes or any other unbalances to make much more gas airflow speed asillustrated in FIGS. 19, 23, and
 24. 11. Gas stove-head with the cover'sinner surface located curving arc ridges (49)(50) between outer (44) andinner (45) ring supply holes that these ridges shall be smaller size(49) and then gradually bigger ahead to the opposite side (50). Thesmaller size side (49) is near gas conduit (47) side to have had gasairflow vent ranging from the big one (51) to the small (52) for airflowfrom gas conduit and gas rest cylinders (30)(32)(34) to have more speedbefore reach to outer and inner ring supply holes and also to manageshape and direction of gas airflow neatly or any other ridges or dentedgrooves between outer and inner ring supply holes or only for outer orinner ring supply holes that are on duty of reducing encounter power ofinner surface of the cover (46) (47) or managing order or increasingspeed of gas airflow before reach to outer or inner supply holes as seenin FIGS. 14, 19, 20, 23, and
 24. 12. Gas stove-head with heat dam-upcylinder (8) that inside characteristic is cup-like arc laid on thecover (6) of outer ring supply holes (44). As for beside and lower sideof the said cylinder has cone-like holes (55) that end of the holes isnear and direct to base area of outer ring flame (53) and along withnumber of hole of heat dam-up cylindrical shape (8) is as the samenumber as of outer ring supply holes tete-a-tete (61). These holes playrole of evacuating oxygen or outer cool air (56) to help combustion atbase of flame (53) tete-a-tete hole (61) or small space or any otherholes at the area of the shapes that play role of blowing outer cool airto help combustion at base of outer ring flame as seen in FIGS. 24, 25and
 26. 13. Gas stove-head with two parts of heat dam-up cylindricalshapes (8) (9) as the inner shape (8) laid upon the cover (6) and theouter shape (9) upon a small part jutted out of the inner shape (82). Alittle distance (64) made small space between the inner shape (8) andthe outer shape (9) and upper edge of the outer shape (9) shall behigher than of the inner shape (8) only a little. The distance made isto dam up heat of outer flame to let outer cool air (65) pass throughlittle gab (64) and push outer flame (53) standing erect to bottom ofutensil as seen in FIGS. 20, 24, 25 and
 27. 14. Gas stove-head withinside side (18) of inner cylindrical shape (17) of gas rest cylinder(5) is thick and zigzag bends lifted afloat (20) to dam up heat of innerring flame (57) and to make heat steam rotate (80). This could helpincrease heat of inner flame or any other curving ridge or groove thathelps heat steam (57) of inner ring flame rotate and increase in heat asseen in FIGS. 8, 14, and
 25. 15. Gas stove-head with cloak-like part (1)on its wings (67) has heat dam-up cylindrical shape (74) located aroundby welding to the end area of inner wings of the part. This is on dutyof keep up heat inside or any other curving ridge upon the wings thatplays the same role as seen in FIG.
 29. 16. Gas stove-head withcloak-like part (1) on its wings (67) has little chambers or holes thatplay role of letting outer cool air (66) to help complete combustion orany space between the parts (70) (72) and the wing (67) that play thesame role as seen in FIG.
 29. 17. Gas stove-head with cloak-like partthat on its wing (67) located heat dam-up cylindrical shape (70) to damup heat within the part up protect outer air to affect flame (53) or anycurving ridge on the inner wing (67) that plays role of dam up heatwithin the part or protect outer air to affect flame (53) or othercylinder attached to utensil legs of inner part that is able to beknocked down or jam-welded that upper most of the shape is higher thaninner wing as seen in FIG.
 20. 18. Gas stove-head with legs for utensil(76) placed upon the wing of the part (67) has curving ridge raisingupwards at a level at upper end of them to lay utensil (76) . This couldhelp flame spread over utensil in case of the utensil has more longerdiameter than the outer wing. The flame shall not touch the shapesattached to end area of outer wing and air (74).
 19. Gas stove-head thathas more than one of gas conduit (13), gas rest cylinder (5) cover ofgas rest cylinder (6) by means of the principle to work of curving ridgeand any other groove to manage order of gas airflow in gas conduit or toincrease in speed of gas airflow by reducing size of air way of theairflow or by the way of travel through curving ridge or any groove orreduce buffet and crash between the airflow or between airflow andsurface by adjust slope or vertical of surface that gas airflow veeredits way and then raised upwards to mouth of gas rest cylinder.